Although the AMD EPYC is definitely a worthy contender in the server space, AMD’s technical marketing of the new CPU has been surprisingly absent, as the company not published any real server benchmarks. The only benchmarks published were SPEC CPU and Stream, with AMD preferring for its partners and third parties to promote performance. And, as our long-time readers know, while the SPEC CPU benchmarks have their merits and many people value them, they are a very poor proxy of most server workloads.

In every launch, we expect companies to offer an element of competitive analysis, often to show how their platform is good or better than the rest. At the launch of Intel’s latest Xeon-SP platform, analysis to EPYC was limited to a high-level, as the systems were not as freely available as expected. AMD was able to do so on Broadwell-E at the time of the EPYC announcement because it was out and available – Intel wasn’t able to do it on EPYC because AMD were several months away from moving it from a cloud-only ramp up program. This is partly the effect of AMD’s server market implementation and announcement roadmap, although it didn’t stop Intel from hypothesising about the performance deficits in ways that caught the attention of a number of online media.

Throughout all of this, AMD could not resist but to continue to tell the world that the “EPYC SoC Sets World Records on SPEC CPU Benchmarks”. In the highly profitable field that is server hardware, this could not be left unanswered by Intel, who responded that the Intel Xeon Scalable has great “momentum” with no less than 110 performance records to date.

Jumping to the present time, in order to to prove Xeon-SP dominance over the competition, Intel’s data center engineering group has been able to obtain a few EPYC systems and has started benchmarking. This benchmarking, along with justifications of third-party verification, was distributed to the small set of Xeon-SP launch reviewers as a guide, to follow up on that high-level discussion some time ago. The Intel benchmarking document we received had a good amount of detail however, and the conference call we had relating to it was filled with some good technical tidbits.

Our own benchmarks showed that the EPYC was a very attractive alternative in some workloads (Java applications), while the superior mesh architecture makes Intel’s Xeon the best choice in other (Databases for example).

A Side Note About SPEC

A number of these records were achieved through SPEC. As mentioned above, while SPEC is a handy tool for comparing the absolute best tweaked peak performance of the hardware underneath, or if the system wants to be analysed close to the metal because of how well known the code base is, but this has trouble transferring exactly to the real world. A lot of time the software within a system will only vaguely know what system it is being run on, especially if that system is virtualised. Sending AVX-512 commands down the pipe is one thing, but SPEC compilation can be tweaked to make sure that cache locality is maintained whereas in the real-world, that might not be possible. SPEC says a lot about the system, but ultimately most buyers of these high-end systems are probing real-world workloads on development kits to see what their performance (and subsequent scale-out performance) might be.

For the purposes of this discussion, we have glossed over Intel’s reported (and verified over at SPEC.org) results.

Pricing Up A System For Comparison

Professionals and the enterprise market will mention, and quite rightly, that Intel has been charging some heavy premiums with the latest generation, with some analysts mentioning a multiple jump up in pricing even for large customers, making it clear that the Xeon enterprise CPU line is their bread and butter. Although Intel’s top-end Xeon Platinum 8180 should give the latest EPYC CPU a fit of trouble thanks to its 28 Skylake-SP cores running at 2.5 to 3.8 GHz, the massive price tag ($10009 for the standard version, $13011 for the high-memory model) made sure that Intel’s benchmarking team had no other choice than also throwing in a much more modest Xeon Platinum 8160 (24 cores at 2.1 – 3.7 GHz, $4702k) as well as the Xeon Gold 6148 (20 cores at 2.4-3.7 GHz, $3072).

SKUS Tested

Intel Xeon
Platinum 8180

Intel Xeon
Platinum 8160

Intel Xeon
Gold 6148

AMD
EPYC 7601

Release Date

Early Q3, 2017

Late Q2, 2017*

Microarchitecture

Skylake-SP with AVX-512

Zen

Process Node

Intel 14nm (14+)

GloFo 14nm

Cores / Threads

28 / 56

24 / 48

20 / 40

32 / 64

Base Frequency

2.5 GHz

2.1 GHz

2.4 GHz

2.2 GHz

Turbo

3.8 GHz

3.7 GHz

3.7 GHz

3.2 GHz

L2 Cache

28 MB

24 MB

20 MB

16 MB

L3 Cache

38.5 MB

33.0 MB

27.5 MB

64 MB

TDP

205 W

150 W

150 W

180 W

PCIe Lanes

48 (Technically 64 w/ Omni-Path Versions)

128

DRAM

6-channel DDR4

8ch DDR4

Max Memory

768 GB

2048 GB

Price

$10009

$4702

$3072

$4200

As a result of this pricing, one of the major humps for Intel in any comparison will be performance per dollar. In order to demonstrate that systems can be equivalent, Intel offered up this comparison from a single retailer. Ideally Intel should have offered multiple configurations options for this comparison, given that a single retailer can intend for different margins on different sets of products (or have different levels of partnership/ecosystem with the manufacturers).

Even then, price parity could only be reached by giving the Intel system less DRAM. Luckily this was the best way to configure the Intel based system anyway. We can only guess how much the benchmarking engineers swore at the people who set the price tags: “this could have been so much easier…”. All joking apart, the document we received had a good amount of detail, and similar to how we looked into AMD’s benchmarking numbers at their launch, we investigated Intel’s newest benchmark numbers as well.